CN1484231A

CN1484231A - Optical record medium and method for recording data into same

Info

Publication number: CN1484231A
Application number: CNA031277756A
Authority: CN
Inventors: 青岛正贵; 井上弘康; 三岛康儿
Original assignee: TDK Corp
Current assignee: TDK Corp
Priority date: 2002-08-12
Filing date: 2003-08-12
Publication date: 2004-03-24
Also published as: EP1394786A1; KR20040014917A; JP4282285B2; CN1956077A; TW200405324A; DE60303719D1; US20040027973A1; JP2004079020A; EP1394786B1; TWI260623B; DE60303719T2

Abstract

An optical recording medium includes a substrate, a first recording layer formed on the substrate and containing an element selected from the group consisting of C, Si, Ge and Sn as a primary component, and a second recording layer located in the vicinity of the first recording layer and containing an element selected from the group consisting of C, Si, Ge and Sn and different from the element contained as a primary component in the first recording layer as a primary component. According to thus constituted optical recording medium, it is possible to optically record data therein and reproduce data therefrom by projecting a laser beam having a wavelength of 350 nm to 450 nm thereonto, which includes two or more recording layers and is capable of decreasing noise level and improving C/N ratio of a reproduced signal.

Description

Optical record medium and with data optical recording method therein

Technical field

The present invention relates to a kind of optical record medium and with the method for data optical recording in this optical record medium, relate in particular to by throwing laser beam that wavelength is 350nm-450nm thereon therein record data and from wherein reappearing the optical record medium of (reproduce) data, it comprises two-layer or several record layers, and can reduce the noise level of the signal that is reappeared and improve its C/N ratio, also relate to the method for optical recording data therein.

Background technology

Optical record medium for example CD, DVD etc. has been widely used as the recording medium that writes down numerical data.These optical record mediums can be rough be divided into the optical record medium that can not write and write data again for example CD-ROM and DVD-ROM (optical record medium of ROM type), can write but the optical record medium that can not write data again for example CD-RW and DVD-RW (but overwriting data type optical record medium) of CD-R and DVD-R (write-once type optical record medium) and the optical record medium that can write data again for example.

Know in this field, usually utilize in the optical record medium manufacture process and come record data in the ROM optical record medium at preformed pit in the substrate, but and in overwriting data type optical record medium, usually utilize the material of phase-change material, utilize the change of optical property that phase transformation causes in the phase-change material to come record data as recording layer.

On the other hand, in the write-once type optical record medium, usually for example cyanine dye, phthalocyanine dye or azo dyes are used as the material of recording layer to adopt organic dyestuff, utilize the changes in optical properties that chemical change causes in the organic dyestuff to come record data, wherein this chemical change is accompanied by physical deformation usually.

But, because organic dyestuff can degrade under being exposed to sunshine etc. the time, so using the stability that is difficult to improve long preservation under the situation of organic dyestuff as recording layer material.Therefore wish to improve the long preservation stability of write-once type optical record medium to be formed with the recording layer of the material outside the organic dye.

The optical recording material of having made as having disclosed a kind of two recording layer laminations that inorganic material is formed among the Japanese Patent Application Publication No.62-204442, this is that a kind of known its recording layer is the optical record medium example that is formed by the material outside the organic dyestuff.

On the other hand, proposed a kind of novel optical recording medium, it can improve recording density and have high data transfer rate.

In this novel optical recording medium, realize that the laser beam spot diameter that recording capacity improves and high data transfer rate can not be avoided requirement is used to write down with playing data for broadcasting is reduced to very little size.

In order to reduce the laser beam spot diameter, the numerical aperture of assembling the object lens of laser beam must be brought up to 0.7 or higher, for example be increased to approximately 0.85, and with the wavelength decreases of laser beam or still less, for example foreshorten to 400nm to 450nm.

Therefore, in the process of a plurality of recording layers that form inorganic material, must selection fully absorbing wavelength be equal to or less than the inorganic material of the blue laser beam of 450nm.

Summary of the invention

Therefore an object of the present invention is to provide a kind of by throwing laser beam that wavelength is 350nm-450nm thereon record data and from the optical record medium of playing data for broadcasting wherein therein, it comprises two or more recording layers, and can reduce the noise level of the signal that is reappeared and improve its C/N ratio, also be provided at the wherein method of optical recording data.

The present inventor has carried out a large amount of research for achieving the above object, found that, C, Si, among Ge and the Sn each is to be that the laser beam of 350nm-450nm has the inorganic material of high light absorption with respect to wavelength, when laser beam is used for being selected from C by containing, Si, a kind of element of Ge and Sn is selected from C as first recording layer of principal ingredient with containing, Si, in the optical record medium that the different element of principal ingredient in a kind of and first recording layer of Ge and Sn constitutes as principal ingredient and near form first recording layer second recording layer during record data, formation comprises the principal ingredient element in first recording layer and the mixed zone of the principal ingredient element in second recording layer, with the reflection coefficient in this district of remarkable change, and come record data with high sensitivity.The inventor also finds, comprises that by utilization the big difference of reflection coefficient between the mixed zone of principal ingredient element in first recording layer and the principal ingredient element in second recording layer and other districts can reduce the noise level of reproducing signal to improve the C/N ratio.

Above-mentioned and other purposes of the present invention can realize that this optical record medium comprises by following optical record medium: substrate, be selected from C, Si, Ge and Sn in containing of forming in the substrate a kind of element as first recording layer of principal ingredient and be arranged near containing first recording layer and be selected from second recording layer of a kind of of C, Si, Ge and Sn element different as principal ingredient with the principal ingredient of first recording layer.

In the present invention, containing specific element means this element as principal ingredient content in first recording layer is maximum in the contained element in first recording layer, is maximum and second recording layer contains specific element means this element as principal ingredient content in the contained element in second recording layer.

In the present invention, not definitely to require second recording layer to contact with first recording layer, just enough as long as second recording layer is positioned near first recording layer with the mixed zone of the principal ingredient that can form the principal ingredient that includes first recording layer and second recording layer in laser emission.In addition, between first recording layer and second recording layer, can insert one or more layers other layer dielectric layer for example.But when one or more layers other layer when for example dielectric layer is inserted between first recording layer and second recording layer, the thickness of this insert layer must equal 30nm or thinner than it, preferably equals 20nm or thinner than it.

In the present invention, preferably forming second recording layer makes it contact with first recording layer.

In the present invention, optical record medium can comprise that one or more layers contains a kind of element of being selected from C, Si, Ge and Sn recording layer as principal ingredient.

Although can form the reason of mixed zone of the principal ingredient of the principal ingredient that comprises first recording layer and second recording layer when illuminating laser beam why also imperfectly understands, but reasonably infer it is the principal ingredient some or all of fusing of meeting or the diffusion of first and second recording layers, form the district of the principal ingredient mixing of one first and second recording layer thus.

The district of mixing the principal ingredient of first and second recording layers and forming is very different with respect to the reflection coefficient of the laser beam of playing data for broadcasting with respect to reflection coefficient and other districts of the laser beam of playing data for broadcasting, and therefore this big difference can highly sensitive reproduction recorded data in the reflection coefficient by utilizing.

In addition, the inventor finds that C, Si, Ge and Sn only have very light influence for environment, and because C and Si are not expensive materials, therefore can reduce the cost of this optical record medium.

Of the present invention one preferred aspect, optical record medium also comprises the photic zone on relative with second recording layer side with first recording layer that is arranged on substrate.

The present invention another preferred aspect, optical record medium also comprises first dielectric layer that is arranged between photic zone and first recording layer and second recording layer, and second dielectric layer between first recording layer and second recording layer and substrate.

According to this preferred aspect of the present invention, can prevent substrate or photic zone reliably because the heat that produces when laser beam radiation comes record data and the distortion that causes therein.In addition, according to this preferred aspect of the present invention,, can prevent more effectively that therefore the recorded data process can variation after long-time owing to can prevent that the element as principal ingredient that contains is corroded in second recording layer.

Of the present invention another preferred aspect, optical record medium also comprises the reflection horizon that is arranged between the substrate and second dielectric layer.

According to this preferred aspect of the present invention, can improve the difference of reflection coefficient between recording areas and the non-recording areas by multiple interference effect, obtain higher reproducing signal (C/N ratio) thus.

In the present invention, be preferably formed first recording layer and second recording layer and make that its gross thickness is 2nm-30nm, more preferably 3-24nm, most preferably 5-12nm.

In the present invention, at least a element that preferably will be selected from Cu, Au, Ag, Pd, Pt, Fe, Ti, Mo, W and Mg joins in first recording layer and/or second recording layer.By in first recording layer and/or second recording layer, adding at least a element that is selected from Cu, Au, Ag, Pd, Pt, Fe, Ti, Mo, W and Mg, can improve the surface smoothness of first recording layer and/the second recording layer, and reduce the noise level of the signal that is reappeared.

In the present invention, optical record medium preferably is constituted as the write-once type optical record medium.

Above-mentioned and other purposes of the present invention also can realize by the method for optical recording data in optical record medium of the following stated, this method comprises: with wavelength is that the laser beam of 350nm-450nm is incident upon on the optical record medium, and described optical record medium comprises: substrate, containing of forming in substrate is selected from C, Si, a kind of element of Ge and Sn is as first recording layer of principal ingredient, and be positioned near containing first recording layer and be selected from C, Si, the different element of principal ingredient in a kind of and first recording layer of Ge and Sn is as second recording layer of principal ingredient; Thereby the element as principal ingredient as containing in the element of principal ingredient and second recording layer that contains in first recording layer is mixed and form record mark.

Of the present invention one preferred aspect, be used for comprising object lens and the laser beam of utilizing its numerical aperture NA and light wavelength lambda to satisfy λ/NA≤640nm in the method for optical record medium optical recording data, and by these object lens laser beam is incident upon on the optical record medium record data in first recording layer and second recording layer thus.

According to this preferred aspect of the present invention,, therefore can improve the recording density of data greatly owing to can reduce the bundle spot of the laser beam that is incident upon on the optical record medium.

Above-mentioned and other purposes of the present invention can be from below in conjunction with clearly understanding the detailed description of accompanying drawing.

Description of drawings

Fig. 1 is the schematic section of the optical record medium structure of the expression preferred embodiment of the invention;

Fig. 2 (a) is the signal amplification sectional view of expression optical record medium shown in Figure 1;

Fig. 2 (b) is a signal amplification sectional view of representing wherein to have recorded the optical record medium of data.

Embodiment

Fig. 1 is the schematic section of the optical record medium structure of the expression preferred embodiment of the invention.

As shown in Figure 1, the optical record medium 10 of this embodiment is constituted as the write-once type optical record medium, comprising: substrate 11, in the reflection horizon 12 that forms on substrate 11 surfaces, second dielectric layer 13 that is forming on 12 surfaces, reflection horizon, at second recording layer 32 that forms on second dielectric layer, 13 surfaces, at first recording layer 31 that forms on second recording layer, 32 surfaces, at first dielectric layer 15 that forms on first recording layer, 31 surfaces and the photic zone 16 that on first dielectric layer, 15 surfaces, forms.

As shown in Figure 1, the core at optical record medium 10 is formed with center pit.

In this embodiment, as shown in Figure 1, laser beam L10 is incident upon on the surface of photic zone 16, thus at optical record medium 10 identifying recording layers or from these optical record medium 10 playing data for broadcasting.

Substrate 11 is used to guarantee optical record medium 10 necessary mechanical strength as supporter.

The material that is used to form substrate 11 has no particular limits, as long as this substrate 11 can be as the supporter of optical record medium 10.Substrate 11 can be formed by glass, pottery, resin etc.In these materials, resin is preferred for forming this substrate 11, because resin is easy to be shaped.The example that is suitable for forming the resin of substrate 40 comprises polycarbonate resin, acrylic resin, epoxy resin, polystyrene resin, polyvinyl resin, acrylic resin, organic siliconresin, fluoropolymer, acrylonitrile butadiene styrene resin, urethane resin etc.In these resins, aspects such as calm workability, optical characteristics, polycarbonate resin is most preferably to be used to form substrate 11.

In this embodiment, the thickness of substrate 11 approximately is 1.1mm.

The shape of substrate 11 has no particular limits, but normally dish type, card shape or sheet shape.

As shown in Figure 1, on the surface of substrate 11, alternately form rill 11a and land 11b.In the time of when record data or when playing data for broadcasting, rill 11a and/or land 11b are as the guide tracks of laser beam L10.

Reflection horizon 12 is used to reflect the laser beam L10 that enters by photic zone 16, thereby it is penetrated from photic zone 16.

The thickness in reflection horizon 12 has no particular limits, but preferably between 10nm-300nm, more preferably between 20nm-200nm.

The material that is used to form reflection horizon 12 has no particular limits, as long as it can reflection lasering beam, reflection horizon 12 can be formed by Mg, Al, Ti, Cr, Fe, Co, Ni, Cu, Zn, Ge, Ag, Pt, Au etc.In these materials, preferably form reflection horizon 12 by metal material with high reflection characteristic, these materials for example are Al, Au, Ag, Cu or the alloy that contains at least a these metals, for example can be the alloys of Al and Ti.

Thereby reflection horizon 12 is set in the reflection coefficient difference that improves by multiple interference effect in first recording layer 31 and second recording layer, 32 optics playing data for broadcasting with laser beam L10 between recording areas and the non-recording areas, obtains high reproducing signal (C/N than) thus.

First dielectric layer 15 and second dielectric layer 13 are used to protect first recording layer 31 and second recording layer 32.The change that can prevent long-time optical recording data afterwards by first dielectric layer 15 and second dielectric layer 13 is bad.Therefore in addition, owing to second dielectric layer 13 also is used to prevent substrate 11 grades because heat is out of shape, can prevent effectively that the signal jitter (jitter) that causes because of the distortion of substrate 11 grades etc. from becoming poorer.

The dielectric material that is used to form first dielectric layer 15 and second dielectric layer 13 has no particular limits, as long as it is transparent, first dielectric layer 15 and second dielectric layer 13 can for example form as the dielectric material of principal ingredient by containing oxide, sulfide, nitride or its combination.In particular, be out of shape because of heat in order to prevent substrate 11 grades, and protect first recording layer 31 and second recording layer, 32, the first dielectric layers 15 and second dielectric layer 13 preferably to contain thus to be selected from Al ₂O ₃, AlN, ZnO, ZnS, GeN, GeCrN, CeO, SiO, SiO ₂, at least a dielectric material among SiN and the SiC as principal ingredient, more preferably first dielectric layer 15 and second dielectric layer 13 contain ZnSSiO ₂As principal ingredient.

First dielectric layer 15 can be formed with different dielectric materials by identical dielectric material with second dielectric layer 13.In addition, at least one in first dielectric layer 15 and second dielectric layer 13 can contain the sandwich construction that comprises a plurality of dielectric films.

In this manual, dielectric layer contain specific dielectric material as the implication of principal ingredient be this dielectric material in this dielectric layer in the contained dielectric material content be maximum, ZnSSiO ₂Mean it is ZnS and SiO ₂Potpourri.

The thickness of first dielectric layer 15 and second dielectric layer 13 has no particular limits, preferably 3nm-200nm.If first dielectric layer 15 or second dielectric layer 13 are thinner than 3nm, then be difficult to obtain above-mentioned advantage.On the other hand, if first dielectric layer 15 or second dielectric layer 13 are thicker than 200nm, then to take a long time and form first dielectric layer 15 and second dielectric layer 13, reduced the throughput rate of optical record medium 10 thus, and can cause in optical record medium 10, cracking (crack) owing in first dielectric layer 15 and/or second dielectric layer 13, have stress (stress).

First recording layer 31 and second recording layer 32 can be used for therein record mark and data being carried out record.In this embodiment, first recording layer 31 is arranged on the side of photic zone 16, and second recording layer 32 is arranged on the side of substrate 11.

In this embodiment, first recording layer 31 contain be selected from C, Si, Ge and Sn element as principal ingredient, second recording layer 32 contain be selected from C, Si, Ge and Sn but the element different with the element that contained in first recording layer as principal ingredient as principal ingredient.

Because each among C, Si, Ge and the Sn is that the light absorption of the red laser beam of 550nm-850nm is equal to or less than about 20% with respect to wavelength X, about wavelength X is that the light absorption of the blue laser beam of 350nm-450nm equals or is higher than approximately 40%, so among C, Si, Ge and the Sn each is applicable to be formed on and wherein utilizes the novel optical recording medium of wavelength X for the blue laser beam record data of 350nm-450nm.

In addition, each among C, Si, Ge and the Sn only has very light burden for environment, and C and Si be not expensive material, therefore can reduce the cost of optical record medium 10.

At least a element that preferably will be selected from Cu, Au, Ag, Pd, Pt, Fe, Ti, Mo, W and Mg joins in first recording layer and second recording layer one or both and adds.By in first recording layer and/or second recording layer, adding at least a element that is selected from Cu, Au, Ag, Pd, Pt, Fe, Ti, Mo, W and Mg, can improve the surface smoothness of first recording layer or second recording layer, and reduce the noise level of the signal that is reappeared.These elements only have very light burden to environment in addition, therefore do not damage the danger of earth atmosphere.

Along with first recording layer 31 and second recording layer, 32 thickenings, radiation has the surface smoothness of first recording layer 31 of laser beam L10 to become poorer.As a result, the noise level of the signal that is reappeared becomes higher, and recording sensitivity reduces.On the other hand, when the integral thickness of first recording layer 31 and second recording layer 32 is too small, before laser beam L10 radiation and reflection coefficient afterwards change little, thereby can not obtain the to have high strength reproducing signal of (C/N than).In addition, be difficult to control the thickness of first recording layer 31 and second recording layer 32.

Therefore, in this embodiment kind, forming first recording layer 31 and second recording layer 32 and making its general thickness is 2nm-30nm.For obtain the to have high strength reproducing signal of (C/N than), and reduce the noise level of reproducing signal, the general thickness of first recording layer 31 and second recording layer 32 is preferably at 3nm-24nm, more preferably at 5nm-12nm.

The thickness separately of first recording layer 31 and second recording layer 32 has no particular limits, but in order to significantly improve recording sensitivity and the greatly reflection coefficient variation of raising laser beam L10 radiation front and back, the thickness of first recording layer 31 is 1nm-30nm preferably, and the thickness of second recording layer 32 is 1nm-30nm preferably.In addition, preferably the thickness of first recording layer 31 and the ratio of the thickness of second recording layer 32 (thickness of the thickness of first recording layer 31/second recording layer 32) are set in 0.2-5.0.

Photic zone 16 is used for transmission laser bundle L10, and preferred thickness is 10 μ m-300 μ m.More preferably, the thickness of photic zone 16 is 50 μ m-150 μ m.

The material that is used to form photic zone 16 has no particular limits, but when photic zone be to adopt under the situation that mode such as spin coating method forms, preferably adopt ultraviolet curable resin, electron beam curing resin etc.More preferably, photic zone 16 is formed by ultraviolet curable resin.

Utilize bonding agent to be bonded on the surface of first dielectric layer by the sheet that light-transmissive resin is made, can form photic zone 16.

Optical record medium 10 with said structure for example can be adopted in the following method and make.

At first in the substrate 11 that is formed with rill 11a and land 11b, form reflection horizon 12.

Can utilize and contain the chemical material that forms reflection horizon 12 and adopt vapor growth method to form reflection horizon 12.The example of this vapor growth method comprises vacuum deposition method, sputtering method etc.

On the surface in reflection horizon 12, form second dielectric layer 13 then.

Also can utilize and contain the chemical material that forms second dielectric layer 13 and adopt vapor growth method to form second dielectric layer 13.The example of this vapor growth method comprises vacuum deposition method, sputtering method etc.

On second dielectric layer 13, also form second recording layer 32.Also can utilize and contain the chemical material that forms second recording layer 32 and adopt vapor growth method to form second recording layer 31.

On second recording layer 32, form first recording layer 31 then.Also can utilize and contain the chemical material that forms first recording layer 31 and adopt vapor growth method to form first recording layer 32.

In this embodiment kind, be 2nm-30nm because first recording layer 31 and second recording layer 32 are formed general thickness, therefore can improve the surface smoothing of first recording layer 31.

On first recording layer 31, form first dielectric layer 15 then.Also can utilize and contain the chemical material that forms first dielectric layer 15 and adopt vapor growth method to form first dielectric layer 15.

At last, on first dielectric layer 15, form photic zone 16.For example can be by on the surface of second dielectric layer 15, applying the acrylic compounds ultraviolet curable resin that is adjusted to proper viscosity or epoxy ultraviolet curable resin, adopt spin coating forming coating, to utilize this coating of ultraviolet radiation then, thus this coating solidified.

Make optical record medium 10 thus.

Record data in the optical record medium 10 of said structure in such a way for example.

Shown in Fig. 1 and 2 (a), utilize laser beam L10 to pass through photic zone 16 at first radiation first recording layer 31 and second recording layer 32 with predetermined power.

In order to come record data with high record density, preferably by numerical aperture NA be 0.7 or higher object lens (not shown) penetrate the laser beam L10 of wavelength X between 350nm-450nm at optical record medium 10 upslides, wherein more preferably λ/NA is equal to or less than 640nm.

In this embodiment, wavelength X is that the laser beam L10 of 405nm is that 0.85 object lens are incident upon on the optical record medium 10 by numerical aperture NA.

Shown in Fig. 2 (b), cause forming the record mark M that the potpourri by the principal ingredient element of the principal ingredient element of first recording layer 31 and second recording layer 32 constitutes like this in the zone of laser beam L10 radiation.

When the principal ingredient element of first recording layer 31 and second recording layer 32 mixes, the reflection coefficient generation significant change that this is regional.Because like this reflection coefficient in the zone of the record mark M that forms and the reflection coefficient of this record mark M peripheral region have differently greatly, therefore can obtain high reproducing signal (C/N ratio) when the reproduction optical recording of information.

When projecting laser bundle L10, laser beam L10 heats first recording layer 31 and second recording layer 32.But in this embodiment, first dielectric layer 15 and second dielectric layer 12 are arranged on the outside of first recording layer 31 and second recording layer 32, can prevent effectively that therefore substrate and photic zone 16 are out of shape because be heated.

According to this embodiment, first recording layer 31 contains and is selected from C, Si, the element of Ge and Sn is as principal ingredient, second recording layer 32 contains and is selected from C, Si, but Ge and Sn different with the element as principal ingredient that contained in first recording layer element is as principal ingredient, and when the laser beam L10 of first recording layer 31 and second recording layer, 32 usefulness predetermined power comes radiation by photic zone 16, what contain in first recording layer 31 mixes in the zone of laser beam L10 radiation as the element of principal ingredient and the element as principal ingredient that contains in second recording layer 32, shown in Fig. 2 (b), form the record mark M that the potpourri by the principal ingredient element of the principal ingredient element of first recording layer 31 and second recording layer 32 constitutes thus, and, therefore when the reproduction optical recording of information, can obtain high reproducing signal (C/N ratio) because like this reflection coefficient in the zone of the record mark M that forms and the reflection coefficient of this record mark M peripheral region have differently greatly.

In addition, because each among C, Si, Ge and the Sn is that the light absorption of the blue laser beam of 350nm-450nm equals or is higher than about 40% with respect to wavelength X, therefore effectively to absorb the wavelength X that is used at novel optical recording medium record data be the blue laser beam of 350nm-450nm for first recording layer 31 of this embodiment optical record medium 10 and second recording layer 32, can form record mark thus fast with record data therein.

In addition, according to this embodiment since in first recording layer 31, contain as the element of principal ingredient and in second recording layer 32, contain as the element of principal ingredient to environment only by very light burden, therefore do not destroy the danger of earth atmosphere.

Working example

In order further to understand these advantages of the present invention, will describe working example below.

Working example 1

Make optical record medium in the following manner.

At first be that 1.1mm, diameter are that the polycarbonate substrate of 120mm is placed on the sputtering equipment with thickness.Then, adopt sputtering method to form in turn on this polycarbonate substrate: the thickness that contains the potpourri of Ag, Pd and Cu is the reflection horizon of 100nm, contain ZnS and SiO ₂The thickness of potpourri be 28nm second dielectric layer, contain Zn as the thickness of principal ingredient be 4nm second recording layer, contain Si and be first recording layer of 8nm and contain ZnS and SiO as the thickness of principal ingredient ₂The thickness of potpourri be first dielectric layer of 22nm.

The ZnS and the SiO that in first dielectric layer and second dielectric layer, are contained ₂Potpourri in, ZnS and SiO ₂Mol ratio be 80: 20.

In addition, adopt the spin coating method utilization that the acrylic compounds ultraviolet curable resin is dissolved in the resin solution formation coating of making in the solvent and on first dielectric layer, form coating, utilize ultraviolet light that this coating is carried out radiation then, solidifying this acrylic compounds ultraviolet curable resin thus, is the photic zone of 100 μ m to form thickness.

Working example 2

Mode according to working example 1 is made optical record medium, contains Si as first recording layer of principal ingredient with contain second recording layer of Ge as principal ingredient but wherein form.

Working example 3

Mode according to working example 1 is made optical record medium, contains second recording layer of C as principal ingredient but wherein form.

Working example 4

Mode according to working example 1 is made optical record medium, contains C as first recording layer of principal ingredient with contain second recording layer of Ge as principal ingredient but wherein form.

Working example 5

Mode according to working example 1 is made optical record medium, contains Si as first recording layer of principal ingredient with contain second recording layer of C as principal ingredient but wherein form.

Working example 6

Mode according to working example 1 is made optical record medium, contains first recording layer of C as principal ingredient but wherein form.

Working example 7

Mode according to working example 1 is made optical record medium, contains first recording layer of Sn as principal ingredient but wherein form.

Working example 8

According to making optical record medium, contain Sn as first recording layer of principal ingredient with contain second recording layer of Ge as principal ingredient but wherein form with working example 1 similar mode.

Working example 9

According to making optical record medium, contain Si as first recording layer of principal ingredient with contain second recording layer of Sn as principal ingredient but wherein form with working example 1 similar mode.

Working example 10

According to making optical record medium, contain Sn as first recording layer of principal ingredient with contain second recording layer of Si as principal ingredient but wherein form with working example 1 similar mode.

Record data in the optical record medium of working example 1-10 manufacturing in such a way.

Specifically, will be placed on Pulstec Industrial Co. in turn according to the optical record medium of working example 1-10 manufacturing, in the DDU1000 optical record medium assessment apparatus that Ltd makes, optical recording data under the following conditions.

Adopting wavelength is that the blue laser beam of 405nm comes record data as laser beam, and utilizing numerical aperture is that 0.85 object lens are focused at this laser beam on each optical record medium by photic zone, therein record data.

Come record data by the power that each optical record medium among the working example 1-10 is changed laser beam.The power definition of laser beam is the power in the lip-deep laser beam of photic zone.

The tracer signal condition is as follows:

Modulation code: (1.7) RLL

Channel bit length: 0.12 μ m

Record linear velocity: 5.3m/sec

Channel clock: 66MHz

Tracer signal: 2T signal and 8T signal

Utilize above-mentioned optical record medium assessment apparatus that the data that write down in each optical record medium are reappeared then, and measure the C/N ratio of the signal that is reappeared.When playing data for broadcasting, the wavelength set of laser beam is at 405nm, and the numerical aperture of object lens is arranged on 0.85.

The maximum C/N that so measures each optical record medium than and the maximum C/N that obtains this reproducing signal than the time laser beam power.

Measurement result is as shown in table 1.

The laser beam peak power of the optical record medium assessment apparatus that is used to test is 10.0mW.Therefore even C/N compares also under the undersaturated situation when the power with laser beam is increased to 10.0mW, thinking then that reproducing signal can have the laser beam power of maximum C/N ratio will be above 10.0mW.This point is expressed as band by the performance number with laser beam ^*10.mW represent.

Table 1

	First recording layer	Second recording layer	??2T ??C/N(dB)	????8T ????C/N(dB)	Laser beam power (mW)
	First recording layer	Second recording layer	??2T ??C/N(dB)	????8T ????C/N(dB)	Laser beam power (mW)	Working example 1	??Ge	??Si	??24.0	????46.6	????10.0 ^*
Working example 2	??Si	??GE	??31.8	????41.3	????8.0	Working example 1	??Ge	??Si	??24.0	????46.6	????10.0 ^*
Working example 2	??Si	??GE	??31.8	????41.3	????8.0	Working example 3	??Ge	??C	??25.2	????46.1	????7.0
Working example 4	??C	??Ge	??24.2	????45.4	????9.0	Working example 3	??Ge	??C	??25.2	????46.1	????7.0
Working example 4	??C	??Ge	??24.2	????45.4	????9.0	Working example 5	??Si	??C	??31.5	????42.1	????7.0
Working example 6	??C	??Si	??31.6	????43.9	????10.0 ^*	Working example 5	??Si	??C	??31.5	????42.1	????7.0
Working example 6	??C	??Si	??31.6	????43.9	????10.0 ^*	Working example 7	??GE	??Sn	??29.0	????41.4	????8.5
Working example 8	??Sn	??Ge	??21.0	????50.6	????10.0 ^*	Working example 7	??GE	??Sn	??29.0	????41.4	????8.5
Working example 8	??Sn	??Ge	??21.0	????50.6	????10.0 ^*	Working example 9	??Si	??Sn	??34.4	????49.6	????6.0
Working example 10	??Sn	??Si	??32.6	????42.1	????5.0	Working example 9	??Si	??Sn	??34.4	????49.6	????6.0

Very clear from table 1, in each optical record medium of working example 1-10 manufacturing, can measure the C/N ratio of reproducing signal, and can utilize wavelength to be the laser beam of 405nm record data therein.

In addition, can make the power of laser beam that in every kind of optical record medium of working example 2-5,7,9 and 10 manufacturings reproducing signal has maximum C/N ratio less than 10mW, the every kind of optical record medium that demonstrates according to working example 2-5,7,9 and 10 manufacturings has excellent record sensitivity.

Below shown and described the present invention with reference to specific embodiment and working example.But should be pointed out that the details that the invention is not restricted to such scheme, can under the situation of the scope that does not break away from claims, carry out changes and improvements.

For example, although first recording layer 31 and second recording layer 32 are contacted in above-mentioned embodiment and working example, but being contacted, first recording layer 31 and second recording layer 32 not indispensable, thus just enough as long as second recording layer 32 can form the mixed zone of principal ingredient of the principal ingredient that comprises first recording layer 31 and second recording layer 32 in illuminating laser beam near first recording layer 31.In addition, can between first recording layer 31 and second recording layer 32, insert one or more layers (for example dielectric layer).

In addition, although the optical record medium 10 of above-mentioned embodiment and working example comprises first recording layer 31 and second recording layer 32, this optical record medium can comprise and contains the element that is selected from C, Si, Ge and Sn one or more recording layer as principal ingredient.

In addition, although first recording layer 31 is arranged on the side of photic zone 16 in above-mentioned embodiment and working example, second recording layer 32 is arranged on the side of substrate 11, but first recording layer 31 can be arranged on substrate 11 1 sides, and second recording layer 32 is arranged on photic zone 16 1 sides.

In addition, the optical record medium 10 in above-mentioned embodiment and the working example comprises first dielectric layer 15 and second dielectric layer 13, and first recording layer 31 and second recording layer 32 are arranged between first dielectric layer 15 and second dielectric layer 13.But optical record medium 10 comprises that first dielectric layer 15 and second dielectric layer 13 are not indispensable, and just this optical record medium 10 can not comprise dielectric layer.In addition, this optical record medium 10 can comprise a dielectric layer, and in this case, for first recording layer 31 and second recording layer 32, dielectric layer can be arranged on the side of substrate 11 or on the side of photic zone 16.

In addition, although first recording layer 31 has identical thickness with second recording layer 32 in above-mentioned embodiment and working example, it is not indispensable that first recording layer 31 and second recording layer 32 have same thickness.

In addition, in above-mentioned embodiment and working example 1-10, although this optical record medium 10 is provided with reflection horizon 12, if form the regional internal reflection light quantity of record mark M but the element as principal ingredient as containing in the element of principal ingredient and second recording layer that contains mixes and do not have the light volume reflection in the zone of projecting laser bundle to be very different each other in first recording layer, can dispense reflection horizon 12 so.

In addition, in the above-described embodiment, although be description about containing extremely thin photic zone and adopting laser beam L10 to carry out from the novel optical recording medium of photic zone one side radiation, but the invention is not restricted to this optical record medium, the present invention can be used for the optical record medium of any DVD type, as long as this optical record medium is that to adopt wavelength to be that the laser beam of 350nm-450nm is carried out data recording just passable.

According to the present invention, a kind of optical record medium can be provided, can be by throwing laser beam that wavelength is 350nm-450nm thereon and record data and from playing data for broadcasting wherein therein, this optical record medium comprises two or more recording layers, can reduce the noise level of reproducing signal, and improving the C/N ratio, the present invention also provides a kind of method of optical recording data therein.

Claims

1. optical record medium comprises: substrate, be selected from C, Si, Ge and Sn in containing of forming in the substrate element as first recording layer of principal ingredient, be arranged near first recording layer and contain be selected from C, Si, Ge and Sn but the different element of the principal ingredient that contains with first recording layer as second recording layer of principal ingredient.

2. optical record medium as claimed in claim 1 wherein forms second recording layer with first recording layer and contacts.

3. optical record medium as claimed in claim 1 or 2 wherein also comprises the photic zone that is provided with respect to first recording layer and second recording layer on a relative side of substrate.

4. optical record medium as claimed in claim 3 wherein also is included in first dielectric layer that is provided with between the photic zone and first recording layer and second recording layer, and second dielectric layer that is provided with between first recording layer and second recording layer and substrate.

5. optical record medium as claimed in claim 4 wherein also comprises the reflection horizon that is arranged between the substrate and second dielectric layer.

6. as each described optical record medium of claim 1-5, wherein this optical record medium is constituted as the write-once type optical record medium.

7. the method for an optical recording data in optical record medium, comprise the steps: be the laser beam of 350nm-450nm in that optical record medium upslide ejected wave is long, wherein this optical record medium comprises: substrate, be selected from C, Si, Ge and Sn in containing of forming in the substrate element as first recording layer of principal ingredient, be arranged near first recording layer and contain second recording layer of the different element of the principal ingredient that still contains with first recording layer that is selected from C, Si, Ge and Sn as principal ingredient; Thus the element as principal ingredient as containing in the element of principal ingredient and second recording layer that contains in first recording layer is mixed mutually and form record mark.

8. as claimed in claim 7 in optical record medium the method for optical recording data, comprise the steps: the object lens and the laser beam that adopt its numerical aperture NA and wavelength X to satisfy λ/NA≤640nm, this laser beam is incident upon on the optical record medium by these object lens, thus record data in first recording layer and second recording layer.

As claim 7 or 8 described in optical record medium the method for optical recording data, wherein optical record medium also comprises the photic zone that is provided with respect to first recording layer and second recording layer on a relative side of substrate, and laser beam is incident upon on this photic zone.